The present invention relates to a process for preparing high yields of hydrosilanes by reacting methylchloropolysilanes with hydrogen gas under pressure at a temperature of from about 25° C to about 350° C in the presence of a copper catalyst. Useful copper catalysts include copper metal, copper salts, and complexes of copper salts with organic ligands.
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1. A process for preparing silanes of the formula Ha Mex SiCl4-(a+x), comprising
A. contacting (1) a polysilane consisting of units of the formula: Mex Cly Si (I), with (2) hydrogen gas under pressure, and B. heating the above admixture to a temperature of from about 25° C to about 350° C, in the presence of a catalytic amount of a copper catalyst, wherein a is 1 to 2, x is 0 to 3, and y is 0 to 3, the sum of a and x being from 1 to 4, the sum of x and y being from 1 to 3; all the silicon atoms in (I) being bonded to at least one other silicon atom and all the valences of the silicon atoms in (I) being satisfied by other silicon atoms, Cl or Me radicals, with the proviso that the polysilane contain at least one Cl group. 5. The process of
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Hydrogenation catalysts for polysilanes are well known in the art. These include both metals and metal salts, which are insoluble in the polysilane reactants, and metal complexes containing organic ligands, which are soluble in the polysilane reactants. However, hydrogenation catalysts disclosed in the prior art generally contain palladium, ruthenium, rhodium, platinum or nickel. Although copper metal, copper salts and copper complexes are well known as catalysts for a wide variety of reactions, most of which are oxidative in nature (see L. F. Fieser and M. Fieser, Reagents For Organic Synthesis, pp. 155-170 (1967)) they have not been considered to be useful as hydrogenation catalysts unless combined with chromium.
For example, U.S. Pat. No. 3,639,105 discloses the preparation of hydrosilanes from alkyl-substituted disilanes and halogen-substituted disilanes by hydrogenation of the disilane at a temperature of from 25° C to 250° C in the presence of a catalyst. The catalysts useful in the process of that patent are Group VIII transition metal catalysts, including organophosphine complexes of those transition metals.
Another publication (see H. Gilman and G. L. Schwebke, "Advances in Organometallic Chemistry", 1, 89 (1964)) discloses the hydrogenation of an unusual cyclic tetraphenyltetrasilane using an initial hydrogen pressure of 800 psi and a reaction temperature of 150° C using a copper chromite catalyst. At the same reaction conditions, hexaethyldisilane failed to cleave. No disclosure was made of the use of a copper catalyst without chromium. The reactivity of halogen-containing polysilanes was not investigated.
Another publication (Chemical Abstracts, 53, 17888 (1959)) discloses the cleavage of the Si-Si bond in methylchlorodisilanes using disilanes in the vapor phase over 5% KOH/Al2 O3 at 500° C to give monosilanes.
The present invention relates in part to a process for preparing high yields of hydrosilanes by reacting methylchloropolysilanes with hydrogen gas under pressure at a temperature of from about 25° C to about 350°C
The process for production of the hydrosilanes that is disclosed in this invention is characterized by a copper catalyst. Useful copper catalysts include copper metal, copper salts, and complexes of copper salts with organic ligands.
This invention relates to a process for preparing silanes of the formula Ha Mex SiCl4-(a+x), comprising
A. contacting
(1) a polysilane consisting of units of the formula:
Mex Cly Si (I),
with
(2) hydrogen gas under pressure, and
B. heating the above admixture to a temperature of from about 25° C to about 350° C, in the presence of a catalytic amount of a copper catalyst,
wherein a is 1 to 2, x is 0 to 3, and y is 0 to 3, the sum of a and x being from 1 to 4, the sum of x and y being from 1 to 3; all the silicon atoms in (I) being bonded to at least one other silicon atom and all the valences of the silicon atoms in (I) being satisfied by other silicon atoms, Cl or Me radicals, with the proviso that the polysilane contain at least one Cl group.
The process of this invention is carried out by reacting (1) and (2) in the presence of the copper catalyst at a temperature of from about 25° C to about 350°C However, to effect the reaction within a reasonable time period of, for example, less than 10 hours, the preferred temperature range is about 100° C to about 350°C Above 350° C, copper catalyst and/or polysilane decomposition may occur, adversely affecting the reaction. Although initial hydrogen pressures of 100 psig or lower may be employed according to the process of the invention, a preferred range of initial hydrogen pressures is from about 500 psig to about 1000 psig. Reaction time is generally less than 10 hours, but it may be longer if desired for some purpose. The preferred reaction time is about 1 hour to about 6 hours.
The process of the invention can be carried out in the presence or absence of a solvent. The amount of solvent employed, if used, is not critical and the primary purpose of the solvent is to facilitate handling of the reaction mixture. If employed, the solvents are those which do not react with chlorosilanes or hydrogen (i.e., inert to the reactants employed in the invention) and can be any such solvent such as linear, cyclic or branched-chain hydrocarbons such as pentane, 2-methylpentane, hexane, cyclohexane, octane and isoctane.
The term "copper catalyst" is intended to include materials wherein the only metal is copper, such as copper metal (e.g., copper powder), copper salts such as copper chlorides (e.g., cuprous and cupric chloride), and copper salts containing organic ligands such as tetramethylethylenediamine copper chloride. Useful cations in the copper salt catalysts of the invention include both Cu(I) and Cu(II), and useful counterions include halide, oxide, sulfide, sulfate, nitrate, hexafluorophosphate, and carbonate. The preferred anion is chloride.
The term "copper catalyst" is also intended to encompass complexes of copper salts with organic ligands such as the product of the reaction of two moles of tributylphosphine with one mole of cupric chloride. Such complexes are prepared by adding the organic compound (e.g., tributylphosphine) to an alcoholic or aqueous/alcoholic solution of copper metal salt and isolating the product.
The amount of copper catalyst employed in the process of this invention is not narrowly critical as long as a catalytically effective amount is present. For purposes of the invention, the amount of copper catalyst present must be at least about 0.2 wt. percent based upon the weight of the polysilane reactant.
The hydrogen gas under pressure useful in the process of the present invention may be fed into the reactor in a single charge. Alternatively, a continuous feed of hydrogen under relatively low pressure (e.g., > 1 atmosphere) into the reactor during the course of the reaction may be made.
The polysilanes which are useful in the process of the present invention are well known in the art. For example, polysilane by-products of the reaction of methyl chloride with silicon metal include Cl2 CH3 SiSiCH3 Cl2, Cl2 CH3 SiSi(CH3)2 Cl, and Cl(CH3)2 SiSi(CH3)2 Cl. Also, hexachlorodisilane and octachlorotrisilane are by-products in the commercial preparation of trichlorosilane from silicon metal and hydrogen chloride. Thus, specific examples of useful polysilanes include: hexachlorodisilane, 1,1-dimethyltetrachlorodisilane, 1,2-dimethyltetrachlorodisilane, 1,1,2-trimethyltrichlorodisilane and 1,1,2,2-tetramethyldichlorodisilane. Also useful are polymeric silanes having more than two silicon atoms such as, 1,1,2,3-tetramethyltetrachlorotrisilane, octachlorotrisilane and dodecylchloropentasilane.
The process of the present invention involves a reaction in which cleavage of the silicon-silicon bond in the above-mentioned polysilanes takes place to form two silicon-hydrogen bonds to produce Ha Mex SiCl4-(a+x) wherein a and x are defined above.
The following examples are given by way of illustration only in order to describe the invention in greater detail, and are not intended to limit the scope thereof.
As used herein, "Me" denotes the methyl group, "%" denotes weight percent, and "psig" denotes pounds per square inch gauge.
PAC Preparation of Soluble Copper CatalystsCertain of the copper catalysts useful in the process of the present invention, namely, those catalysts containing an organic ligand, are soluble in the polysilane reactant mixture. These catalysts are prepared by adding the organic ligand dissolved in methanol to a methanolic solution of a metal chloride at room temperature. Solid catalyst products were collected by filtration. Liquid catalyst products, such as the tributylphosphine complex of copper chloride, were obtained by removing the solvent under vacuum.
Except as otherwise noted in Table I below, the following polysilane reactant charge was used in Runs 1 to 47:
| ______________________________________ |
| Weight Percent Of |
| Charge Component |
| Total Charge |
| ______________________________________ |
| Cl2 MeSiSiMeCl2 |
| 56.7 |
| Cl2 MeSiSiMe2 Cl |
| 29.7 |
| ClMe2 SiSiMe2 Cl |
| 5.2 |
| Me3 SiSiMeCl2 |
| 3.5 |
| Me3 SiSiMe2 Cl |
| 5.4 |
| Others 3.5 |
| ______________________________________ |
A charge of polysilanes equal to about 43 - 45 grams was introduced into a 300 milliliter stainless steel rocking autoclave which had first been cleaned with an abrasive cleanser and wire brush and then dried and purged with nitrogen. Next, solid or liquid catalyst was added to the polysilane mixture, the autoclave was pressurized with hydrogen, rocking of the autoclave was begun, and heat was applied to the mixture through an external jacket. The temperature was raised to the desired point and maintained for the period of time shown in Table I. The autoclave was allowed to cool sufficiently to prevent loss of volatile products, vented, and opened in order to recover the product mixture.
Using an alternative procedure when there was a ten-fold scale-up of reactants and a 3-liter autoclave was used (see Run 17, Table I below), the product mixture was obtained from the autoclave by displacement through a dip tube utilizing residual internal gas pressure in the autoclave.
The product yields, expressed as weight percents based on the total amounts of polysilane reactant charge, were determined by gas chromatography. Although not shown in the results presented in Table I, trace amounts of H3 MeSi were observed in most of the reactions. The results are presented in Table I which follows.
| TABLE I |
| THE CATALYTIC SYNTHESIS OF HYDROSILANES FROM POLYMETHYLCHLOROSILANES |
| Wt-% yield monomersa wt-% Psig % Hydro Wt-%d Additive No. C |
| atalyst Compound Catalyst H2 ° C Hr Convers. Me2 |
| SiCl2 MeSiCl3 Me3 SiCl HMeSiCl2 HMe2 SiCl |
| H2 |
| MeSiCl Total silanes residues Compound Wt-% 1 |
| None -- 1000b 350 5.5 60 6 6 NAc 0 0 NA 12 0 48 2 None -- |
| 1000 350 1. 50 8 8 NA 4 tre NA 20 4 30 3 None -- 1000 275 5. 5 NA |
| NA NA NA NA NA NA NA NA 4 (φ3 P)2 PdCl2 0.3 1000 275 |
| 5. 30 1 5 NA 4 tre NA 10 4 20 5 (φ 3 P)2 PtCl2 |
| 0.35 1000 275 5 10 1 2 NA 4 1 NA 8 5 2 6 (φ3 P)2 |
| PtCl2 m 0.35 1000 350 1. 45 3 4 NA 3 tre NA 10 3 35 7 |
| (φ3 P)3 RuCl2 0.4 1000 275 2.5 25 1 3 NA 1 tr NA 5 1 |
| 20 8 (φ3 P)2 Rh(CO)Cl 0.4 1000 275 5. 10 2 4 NA 3 1 NA 10 |
| 4 0 9 Co2 (CO)3 0.8 1000 350 1. 25 5 5 NA 2 0 NA 12 2 13 10 |
| CoSx 1.2 1000 350 1. 59 10 11 4 14 3 4 46 21 13 11 Copper chromite |
| 0.5 1000 275 17.5 40 3 2 NA 15 3 NA 23 18 17 12 Copper chromite 0.2 1000 |
| 350 1. 70 11 6 NA 18 2 NA 37 20 33 13 Copper chromite 0.2 1000 350 16. |
| 100 18 11 NA 32 6 NA 67 38 33 14 CuCl 1. 1000 350 1. 96 22 11 4 39 7 |
| 14 95 60 0 15b CuCl 1. 1000 355 1. 96 20 11 4 34 8 13 90 55 6 |
| 16g CuCl 1. 1000 340-60 1. 91 23 12 3 32 7 12 89 51 2 17h CuCl |
| 1. 1000 325 2. 82 14 6 3 34 8 11 76 53 6 18 CuCl 1. 1000 350 3. 98 26 16 |
| 3 27 6 7 85 40 13 19 CuCl 1. 1000 350-75 1. 96 14 8 2 22 4 9. 59 35 37 |
| 20 Cu powder 0.44 1000 350 1. 96 15 6 3 37 8 10 79 55 17 21 Cu powder |
| 0.11 1000 350 1. 28 6 3 1 7 1 1 19 9 9 22 CuCl 1. 1000 350 1. 88 17 9 3 |
| 34 8 11 82 53 6 AlCl3 0.33 23 CuCl 1. 1000 280 5. 24 7 1 1 12 1 2 |
| 24 15 0 AlCl3 0.33 24 CuCl 1. 1000 325 2. 98 33 9 2 27 7 11 89 45 9 |
| AlCl3 1.3 25 CuCl 1. 1000 360 1.3 66 5 5 2 22 5 7 46 34 20 ZnCO |
| 3 0.32 26 CuCl 1. 1000 350 1.8 54 11 8 2 6 1 1 29 8 25 ZnCO3 1.3 27 |
| 30/70 Cu/Si alloy 2.2 1000 340-60 1. 99 20 11 4 36 7 15 93 58 6 -- 28 NP |
| Raney Nil 0.4 1000 350 1. 95 18 8 3 37 8 13 87 58 8 -- 29 NP Raney |
| Ni 0.4 1000 350 1. 97 20 9 7 33 7 15 91 55 6 Me4 Si 13. 30 Ni on |
| kieselguhrj 1.1 1000 350 1. 95 15 16 3 29 8 14 85 51 10 -- 31 Ni,Zr |
| on kieselguhrk 1.1 1000 350 1. 80 14 15 2 24 7 13 75 44 5 -- 32 |
| (MeOCH2 CH2 OMe)NlCl2 0.7 1000 350 1. 66 12 7 2 25 5 7 58 |
| 37 8 -- 33 (Bu3 P)2 PdCl2 1. 500 120 4. 49 tr 8 tr 20 tr t |
| re 28 20 21 -- 34 (Bu3 P)2 PdCl2 1. 600 150 6. 72 5 |
| 23 tr 17 1 tre 46 18 26 -- 35 2Bu2 P.CuCl2l 2. 500 |
| 200 4. 84 15 13 2 36 1 10 77 47 7 -- 36 2Bu2 P.CuCl2 1. 600 |
| 150 6. 84 16 12 2 43 1 12 86 56 0 -- 37 CuCl2 0.26 600 150 6. 78 |
| 16 29 1 1 0 0 47 1 31 Bu2 P 1.5 38 2φBu2 P.CuCl2 1. |
| 600 150 6. 67 11 18 2 5 0 tre 36 5 31 -- m 39 2φ2 |
| P.CuCl2 1. 600 150 6. 28 1 1 tr tr 0 0 2 0 26 -- 40 (Me2 |
| NCH2 CH2 NMe2)CuCl2 1. 600 150 22. 75 10 22 1 15 tr |
| 1 48 16 27 -- 41 (C16 H33 NMe2)2 CuCl3 1. 600 |
| 150 6 45 1 8 tr 4 0 tr 13 4 32 42 (acac)2 Cu 1. 600 150 6. 4 1 1 |
| tr 1 0 0 3 1 1 43 (Bu3 P)2 NlCl2 2. 1000 200 4. 84 7 14 1 |
| 30 4 8 64 42 20 44 (Bu3 P)2 NlCl2 1. 600 150 6.5 86 17 |
| 15 2 37 tre 13 84 50 2 45 (Bu3 P)2 NlCl2 1. 750 100 |
| 6.5 86 17 11 2 43 tre 11 84 54 2 46 (Bu3 P)2 NlCl2 |
| 0.5 750 100 3.0 84 16 10 2 43 2 11 84 54 0 47 (Bu3 P)2 |
| NlCl2 0.2 |
| a The present yields are rounded to the nearest percent. |
| b Nitrogen pressure rather than hydrogen pressure. |
| c "NA" denotes "not analyzed". |
| d Wt. % residues = Percent of starting material converted - Percent |
| of total monomers obtained. |
| e "tr" denotes "trace" (less than 1%). |
| f Disilanes with all normally accompanying solids removed. |
| g Disilanes with abnormal amount of accompanying solids. |
| h Ten-fold scale up in materials and autoclave. |
| i Deactivated, non-pyrophoric. |
| j 50% Ni, Girdler Catalyst No. G-49B. |
| k 50% Ni, 2% Zr, Girdler Catalyst No. G-69. |
| l Product of 2 Bu3 P and 1 CuCl2 in methanol. |
| m "φ" denotes phenyl group. |
The results as presented in Table I show copper to be an effective hydrogenation catalyst in various forms, including CuCl (Runs 14 - 19), copper powder (Runs 20 - 21), CuCl in the presence of AlCl3 (Runs 22 - 24), CuCl in the presence of ZnCO3 (Runs 25 - 26), the complex prepared from tributyl phosphine and copper chloride (Runs 35 - 36), and (Me2 NCH2 CH2 NMe2)CuCl2 (Run 40).
It is to be noted that high yields of hydrosilane monomers are obtained using 1 wt. % CuCl catalyst based on the weight of polysilane reactant at 350° C and 1000 psig with a reaction time of 1 hour (see Runs 14 - 16 wherein hydrosilane monomer yields are 60%, 55%, and 51% respectively). It should also be noted that a high total yield of hydrosilane monomers (55% yield) is obtained using a very small amount of copper catalyst (0.44 wt. % of copper powder based upon the weight of the polysilane reactant - see Run 20). Moreover, Run 36 provides a high yield of hydrosilane monomers (56%) under mild conditions (600 psig H2, 150° C) using a small amount of copper catalyst (1 wt. % of 2Bu3 P.CuCl2 ≈ 0.12 wt. % net copper).
It is surprising that copper provides a hydrogenation catalyst for polysilanes that is comparable in effectiveness to that of Raney nickel -- long considered to be an excellent hydrogenation catalyst -- under similar reaction conditions. For example, Run 20 using 0.44 wt. % copper powder catalyst provides the same yield of hydrosilanes as is provided in Run 29 using 0.4 wt. % Raney nickel catalyst (55% hydrosilanes) under identical conditions.
The product mixture obtained using Run 17 (wherein 430 grams of a disilane mixture was reacted in a 3-liter rocking autoclave) was distilled to give 326 grams of a mixture of monomeric silanes, 77 grams of a mixture of disilanes, and 2% of a residue. The recovered disilane mixture was divided into two parts. One half of the disilane mixture was reacted with hydrogen at 1000 psig in the presence of a copper chloride catalyst. The other half of the disilane mixture was reacted with hydrogen at 1000 psig in the presence of a Raney nickel catalyst. A determination was made of the extent of reaction for each catalyst and of the amount of unreacted disilane which was available for further reaction by recycling. The results are presented in Table II below.
| TABLE II |
| ______________________________________ |
| Catalyst 1 wt. % CuCl |
| 0.4 wt. % Ni |
| Reaction Temperature |
| 325° C |
| 350° C |
| Reaction Time 2.5 hours 1 hour |
| Weight Percent Monomer Products |
| H2 MeSiCl 3 6 |
| HMe2 SiCl 3 2 |
| HMeSiCl2 15 21 |
| Me3 SiCl 2 2 |
| MeSiCl2 8 9 |
| Me2 SiCl2 |
| 6 9 |
| Percent Conversion 40-50 70 |
| ______________________________________ |
In order to determine whether the obtaining of the products H2 MeSiCl, MeSiCl3, and HMeSiCl2 was dependent upon redistribution reactions (such as H2 MeSiCl + MeSiCl3 ⇄ 2 HMeSiCl2), an experiment was carried out using a product mixture containing 12 wt. % MeSiCl3 (more than normally expected to be found in a product mixture. See Run 28 where ∼ 8 wt. % MeSiCl3 was formed). After 1 hour at 350° C in the presence of 0.4 wt. % Raney nickel catalyst, the yield of new monomers was given in Table III. As can be seen by comparison with the results of Run 28, no substantial change in product distribution had occurred (note especially the amounts of H2 MeSiCl and new MeSiCl3 formed).
| TABLE III |
| ______________________________________ |
| Wt. Percent Yield |
| Monomer Example 3 Run 28 (Table I) |
| ______________________________________ |
| H2 MeSiCl |
| 11 13 |
| Hme2 SiCl |
| 6 8 |
| HMeSiCl2 |
| 38 37 |
| Me3 SiCl |
| 3 3 |
| MeSiCl3 5 8 |
| Me2 SiCl2 |
| 24 18 |
| Percent conversion |
| 96 91 |
| ______________________________________ |
Fifty pounds of a mixture of polysilanes obtained as by-products of the reaction of silicon with methyl chloride and comprising 9.1 wt. percent of compounds having a boiling point of less than 149° C, 3.3 percent with a boiling point of greater than 159° C, 4.2 percent of Me4 Si2 Cl2, and 83.5 percent of a mixture of Me3 Si2 Cl3 and Me2 Si2 Cl4, was charged into a 50 gallon stirred autoclave. The 2Bu3 P.CuCl2 catalyst was added (225 grams, 1 wt. percent), and 600 psig hydrogen pressure was applied at 25°C The resulting molar ratio of H2 : disilanes was about 0.5:1. The mixture was heated to 150° C and an 800 psig pressure was maintained by hydrogen addition during the ensuing 6.5 hour reaction period. After cooling and venting, the following product mixture resulted:
| ______________________________________ |
| H2 MeSiCl 9.2 wt. % |
| HMe2 SiCl 1.2 |
| HMeSiCl2 37.4 |
| Me3 SiCl 0.6 |
| MeSiCl3 12.8 |
| Me2 SiCl2 |
| 17.8 |
| compounds bp 71° - 149° |
| 13.4 |
| Me4 Si2 Cl2 |
| 3.6 |
| Me3 Si2 Cl3 + Me2 Si2 Cl4 |
| 0.8 |
| compounds bp > 159° |
| 2.5 |
| ______________________________________ |
Another reaction was performed at 1 atmosphere hydrogen pressure in the liquid phase to obtain hydrosilanes from polysilanes. A 200 milliliter flask was equipped with a magnetic stirrer, thermometer, coarsegrade filter stick, and a 6 inch Vigreaux column topped in turn by an 8 × 0.6 inch tube that opened at the top to a surrounding water-jacketed space having a drain line at the bottom. After flushing the flask with nitrogen and adding 1 gram of (Bu3 P)2.NiCl2 to the flask, 104 grams of the polysilane mixture used in the Runs of Table I were charged into the flask and a hydrogen flow was begun through the filter stick at 145 milliliters per minute. The mixture was heated to 90° C and maintained in the range of 89° - 104° C for 4.5 hours, during which time 36.1 grams of monomers were collected. There was obtained 68.5 grams of residue comprising no more than traces of monomers and disilanes except for the mainly unreacted compounds Me2 ClSiSiClMe2 and Me3 SiSiClMe2. The monomer mixture contained the following silanes:
| ______________________________________ |
| Monomer Yield (wt. percent) |
| ______________________________________ |
| H2 MeSiCl 3.9 |
| HMe2 SiCl tr |
| HMeSiCl2 15.5* |
| Me3 SiCl 4.5 |
| MeSiCl3 31.7 |
| Me2 SiCl2 |
| 44.5 |
| ______________________________________ |
| *Reactant contained 5.4 wt. percent HMeSiCl2 |
The reaction was repeated at 100° C and 150° C using 2 wt. percent of the copper catalyst. Except during an initial period when Me3 SiSiMeCl2 was selectively consumed, no significant amount of hydrosilanes was produced.
Reactions were performed at 1 atmosphere pressure in the vapor phase over a nickel on kieselguhr catalyst and a copper on aluminum oxide (Cu/Al2 O3) catalyst, and the results were compared with a standard run in the absence of a catalyst. The catalyst chips were placed in a vertical, resistance heated Vycor reactor tube containing an annular thermocouple well having an effective volume of 1.4 cubic centimeter per centimeter of reactor length and activated with hydrogen at 40 milliliters per minute at 500°-650°. The reaction was begun at 550° C by pumping the polysilane mixture (see Example 1 for the composition of the polysilane mixture) at rates which provided 10 to 32 seconds contact time, based on free volume, and at molar ratios of H2 to disilanes of 1.0 to 7.7, as determined from the gas and liquid feed rates. The ranges of molar ratios of products obtained per mole of MeSiCl3 using the nickel catalyst were HMeSiCl2, 0.56-0.77; HMe2 SiCl, 0.19- 0.44; and Me2 SiCl2, 0.71-0.83 at 74-100% conversion of the tri and tetrachlorodisilane components. Similar results were obtained using the copper catalyst, except that more Me2 SiCl2 than MeSiCl3 was obtained. A comparison of the catalyzed reaction versus the uncatalyzed standard follows:
| ______________________________________ |
| Standard |
| Ni/Kieselguhr |
| No Catalyst |
| ______________________________________ |
| ° C 550 550 |
| Contact time, seconds |
| 17 15 |
| Molar ratio of hydro- |
| 7.7 5.0 |
| gen to disilanes |
| wt. percent yield |
| H2 MeSiCl 4.4 1.5 |
| HMe2 SiCl 7.2 9.3 |
| HMeSiCl2 19.6 12.5 |
| Me3 SiCl 2.4 3.8 |
| MeSiCl3 33.5 27.0 |
| Me2 SiCl2 |
| 21.4 30.0 |
| Wt. percent unreacted |
| 11.5 16.0 |
| disilanes |
| Wt. percent yield hydro- |
| 31.2 23.3 |
| silanes |
| ______________________________________ |
This experiment was carried out to determine whether a recovered liquid catalyst concentrate could be reused effectively in a subsequent reaction. A mixture (which had previously been heated for 7 hours at 100° C under 750 psig of hydrogen with only 22 wt. percent conversion of disilanes and formation of only 4 wt. percent monomers) of 50 grams of polysilane reactants (see Example 1 for the composition of the polysilane reactants) and 1 wt. percent of 2Bu3 P.CuCl2 catalyst was heated at 150° C under 600 psig of hydrogen at 25° C for 6 hours whereupon Mixture A resulted. Mixture A was then distilled at 60° C and 15 millimeters of Hg along with 5 grams of the 8 grams analytical sample removed following the 100° C treatment. The residue was cooled under nitrogen when disilanes began to reflux in the head of the reactor. Nine grams of combined polysilanes and catalyst was mixed with 40 grams of fresh disilane mixture and treated under 600 psig of hydrogen for 6 hours at 150°C Mixture B was obtained, demonstrating that the catalyst was substantially effective upon reuse.
| ______________________________________ |
| Mixture A Mixture B |
| ______________________________________ |
| Wt. Percent H2 MeSiCl |
| 12 12 |
| HMe2 SiCl |
| tr tr |
| HMeSiCl2 42 34 |
| Me3 SiCl 2 1 |
| MeSiCl3 12 17 |
| MeSiCl2 16 17 |
| Total monomers 84 81 |
| Total hydrosilanes |
| 54 46 |
| Percent conversion |
| 86 93 |
| Percent residue |
| 2 12 |
| ______________________________________ |
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